Nervous system dynamics during fragmentation and regeneration in Enchytraeus japonensis (Oligochaeta, Annelida).

Enchytraeus japonensis is a small terrestrial oligochaete which primarily reproduces asexually by fragmentation and regeneration. In order to introduce a molecular approach to the study of regeneration we developed a whole-mount immunostaining procedure for the worm. Using an antibody directed against acetylated tubulin in conjunction with confocal laser-scanning microscopy, we succeeded in clarifying the three- dimensional structure of the entire nervous system in the full-grown worm and its dynamics during the fragmentation and regeneration process. In addition, we examined the expression of neurotransmitters and neuropeptides in the worm using a fluorescently-labeled antagonist and various antibodies. In particular, we found two circumferential structures in the body wall muscle of each segment that react strongly with alpha-bungarotoxin, an antagonist of nicotinic acetylcholine receptors, and detected nerve fibers just underneath these structures. During the fragmentation process, the circular body wall muscles contract near one of these circumferential structures in the middle of the segment, which causes constriction and results in fission of the body. This alpha-bungarotoxin-positive structure was designated the neuromuscular junction of the circular muscle. During the regeneration process nerve fibers grow from the remaining ventral nerve cord and gradually form networks in both the anterior and posterior regeneration buds. The growing fibers extend to the prostomium (a sensory organ) at the anterior end prior to connecting to the presumptive brain rudiment. A neural network appears around the pygidium, and this is followed by growth of the body at the posterior end. The nervous system appears to play an important role in both anterior and posterior regeneration.

Expression of the Lewis group carbohydrate antigens during Xenopus development.

We have examined the pattern of expression of the Lewis group carbohydrate antigens during the development of African toad Xenopus laevis. One of these antigens, Lewis x (Le(x), also known as SSEA-1), was previously shown to be involved in cell-cell adhesion in early mouse embryos and teratocarcinoma stem cells. Recently another member of these antigens, sialyl-Le(x), was found to be one of the major ligands for the selectin family of cell-cell adhesion molecules. In order to study the role of carbohydrate-mediated cell adhesion during Xenopus development, we first studied the expression pattern of the Le(x). We found that Le(x)was not expressed in early embryos, started to be expressed at the tail bud stage in anterior regions of the body such as the cement gland or head skin, and was gradually showed more posterial expression at later stages. At tadpole stage, it was also expressed on specific cell bodies in brain, and in axon region in brain and neural retina. Antibodies against Le(x)blocked neurite outgrowth in the explant culture of tadpole brain. One of the candidates for Le(x)carrier protein in the tadpole brain is a 200 kDa glycoprotein detected by Western blotting. In adult tissues, it was expressed in brain, testis, and gut, but not in kidney, lung, spleen, ovary, or muscle. We also examined the expression patterns of other Lewis group antigens. Among them, sialyl-Le(x)was expressed on endothelial cells and on leukocytes, suggesting the possibility that it functions as a ligand for selectin in Xenopus.

Fragmenting oligochaete Enchytraeus japonensis: a new material for regeneration study.

Enchytraeus japonensis, a recently described terrestrial oligochaete, reproduces asexually by fragmentation and subsequent regeneration. Taking notice of its high potential as a new material for regeneration study, detailed studies were undertaken on the regeneration and reproduction of E. japonensis. The full-grown body divided into 6-13 fragments that regenerated into complete individuals in 4 days, grew to full length in 10 days, and then fragmented again. Regeneration of the head and tail was epimorphic, involving blastema formation, while old segments in the regenerating fragment morphallactically transformed into the appropriate segments to retain the proper body proportions, which could be visualized by histochemistry for alkaline phosphatase. Artificially cut fragments regenerated either normally or into dicephalic monsters with biaxial heads depending on the conditions. Fragmentation could be induced by decapitation, and sexual reproduction was also found inducible in the laboratory. These findings, together with its simple metameric morphology and ease of culture and handling, suggest that E. japonensis is an excellent material for studying animal regeneration.

A functional test for maternally inherited cadherin in Xenopus shows its importance in cell adhesion at the blastula stage.

We report here on the consequences of reducing the expression of EP-cadherin at the earliest stages of Xenopus development. Injection of oligodeoxynucleotides antisense to maternal EP-cadherin mRNA into full-grown oocytes reduced the mRNA level in oocytes, and the protein level in blastulae. Adhesion between blastomeres was significantly reduced, as seen in whole embryos, and in assays of the ability of blastomeres to reaggregate in culture. This effect was especially conspicuous in the inner cells of the blastula and included the disruption of the blastocoel. The severity of the EP-cadherin mRNA depletion and of the disaggregation phenotype was dose dependent. This phenotype was rescued by the injection into EP-cadherin mRNA-depleted oocytes of the mRNA coding for a related cadherin, E-cadherin, that is normally expressed at the gastrula stage in the embryonic ectoderm.

Monoclonal antibody ECCD-1 inhibits intercellular communication in teratocarcinoma PCC3 cells.

The monoclonal antibody ECCD-1 recognizing a certain class of cell surface proteins inhibits the Ca2+-dependent cell-to-cell adhesion in teratocarcinoma stem cells. In this paper, we studied the effect of ECCD-1 on cell-to-cell communication in PCC3 cells by measuring the transfer of lucifer yellow between cells. To this aim, PCC3 cells were cultured in the presence of ECCD-1 for various periods, and then the fluorescent dye was injected into a cell located in the center of cell colonies, followed by counting number of cells to which the dye was transferred. The results showed that ECCD-1 inhibits the dye transfer between cells, suggesting that the Ca2+-dependent cell-to-cell adhesion system (CDS) is essential for the functions of gap junction.

Molecular nature of the calcium-dependent cell-cell adhesion system in mouse teratocarcinoma and embryonic cells studied with a monoclonal antibody.

The molecular nature of the Ca2+-dependent cell-cell adhesion system in mouse teratocarcinoma (t-CDS) was studied using a monoclonal antibody recognizing t-CDS. We isolated a hybridoma clone producing a monoclonal antibody (ECCD-1) able to disrupt cell-cell adhesion when added to monolayer cultures of teratocarcinoma cells. This antibody bound to the cells with intact t-CDS, resulting in an inhibition of their aggregation, but did not bind to cells from which t-CDS was removed by trypsin treatment in the absence of Ca2+. The binding of ECCD-1 to cell surfaces required Ca2+ but not other ions. Western blot analysis showed that ECCD-1 recognizes multiple cell surface proteins, the major one of which is a component with a molecular weight of 124,000. The binding of ECCD-1 to these antigens was Ca2+-dependent even in cell-free systems, suggesting that the molecules involved in t-CDS undergo conformational changes by binding with Ca2+, leading to conversion of their molecular structure into an active form. ECCD-1 also reacted with 8-cell stage mouse embryos and with certain types of epithelial cells (excluding fibroblastic cells) in various differentiated tissues collected from mouse fetuses, again affecting their cell-cell adhesion. We also showed that a monoclonal antibody (DE1) raised against gp84 (F. Hyafil et al., 1981, Cell 26, 447-454) recognizes the same antigens as ECCD-1.

Calcium-dependent cell-cell adhesion molecules common to hepatocytes and teratocarcinoma stem cells.

The molecules involved in Ca2+-dependent cell-cell adhesion systems (CDS) in mouse hepatocytes were characterized and compared with those in teratocarcinoma cells. Fab fragments of antibody raised against liver tissues (anti-liver) inhibited Ca2+-dependent aggregation of both liver and teratocarcinoma cells. A monoclonal antibody raised against teratocarcinoma CDS (ECCD-1) also inhibited the Ca2+-dependent aggregation of these two cell types equally. These antibodies induced disruption of cell-cell adhesion in monolayers of hepatocytes. Thus, CDS in these two cell types are not immunologically distinctive. Immunochemical analyses with these antibodies showed that CDS in both hepatocytes and teratocarcinoma cells involved at least two classes of cell surface proteins with molecular weights of 124,000 and 104,000. ECCD-1 selectively bound to hepatocytes but not to fibroblastic cells in liver cell cultures. Thus, the molecular constitution of CDS in hepatocytes and teratocarcinoma stem cells is identical. As ECCD-1 reacts with other classes of embryonic and fetal cells, the molecules identified here could have a major role in cell-cell adhesion in various tissues at any developmental stage of animals.